Provided by: libchi-perl_0.60-3_all 
NAME
CHI - Unified cache handling interface
VERSION
version 0.60
SYNOPSIS
use CHI;
# Choose a standard driver
#
my $cache = CHI->new( driver => 'Memory', global => 1 );
my $cache = CHI->new( driver => 'RawMemory', global => 1 );
my $cache = CHI->new( driver => 'File',
root_dir => '/path/to/root'
);
my $cache = CHI->new( driver => 'FastMmap',
root_dir => '/path/to/root',
cache_size => '1k'
);
my $cache = CHI->new( driver => 'Memcached::libmemcached',
servers => [ "10.0.0.15:11211", "10.0.0.15:11212" ],
l1_cache => { driver => 'FastMmap', root_dir => '/path/to/root' }
);
my $cache = CHI->new( driver => 'DBI',
dbh => $dbh
);
my $cache = CHI->new( driver => 'BerkeleyDB',
root_dir => '/path/to/root'
);
# Create your own driver
#
my $cache = CHI->new( driver => '+My::Special::Driver', ... );
# Cache operations
#
my $customer = $cache->get($name);
if ( !defined $customer ) {
$customer = get_customer_from_db($name);
$cache->set( $name, $customer, "10 minutes" );
}
my $customer2 = $cache->compute($name2, "10 minutes", sub {
get_customer_from_db($name2)
});
$cache->remove($name);
DESCRIPTION
CHI provides a unified caching API, designed to assist a developer in persisting data for
a specified period of time.
The CHI interface is implemented by driver classes that support fetching, storing and
clearing of data. Driver classes exist or will exist for the gamut of storage backends
available to Perl, such as memory, plain files, memory mapped files, memcached, and DBI.
CHI is intended as an evolution of DeWitt Clinton's Cache::Cache package, adhering to the
basic Cache API but adding new features and addressing limitations in the Cache::Cache
implementation.
FEATURES
• Easy to create new drivers
• Uniform support for namespaces
• Automatic serialization of keys and values
• Multilevel caches
• Probabilistic expiration and busy locks, to reduce cache miss stampedes
• Optional logging and statistics collection of cache activity
CONSTRUCTOR
To create a new cache object, call "<CHI->new". It takes the common options listed below.
driver is required; all others are optional.
Some drivers will take additional constructor options. For example, the File driver takes
"root_dir" and "depth" options.
You can configure default options for each new cache object created - see "SUBCLASSING AND
CONFIGURING CHI".
Note that "CHI->new" returns an instance of a subclass of CHI::Driver, not "CHI".
compress_threshold [INT]
A value in bytes. Automatically compress values larger than this before storing.
Requires Compress::Zlib to be installed. Defaults to undef, meaning no automatic
compression. Inspired by the parameter of the same name in Cache::Memcached.
# Compress values larger than 1MB
compress_threshold => 1024*1024
driver [STRING]
Required. The name of a cache driver, for example "Memory" or "File". CHI will prefix
the string with "CHI::Driver::", unless it begins with '+'. e.g.
driver => 'File'; # uses CHI::Driver::File
driver => '+My::CHI::Driver::File' # uses My::CHI::Driver::File
expires_in [DURATION], expires_at [INT], expires_variance [FLOAT]
Provide default values for the corresponding "set" options.
expires_on_backend [NUM]
If set to 0 (the default), CHI alone is aware of the expiration time and does not pass
it along to the backend driver. This allows you to use "get_object" to retrieve
expired items.
If set to 1, pass expiration times to backend driver if the driver supports it -- for
example, CHI::Driver::Memcached and CHI::Driver::CacheCache. This may allow the driver
to better manage its space and evict items. Note that only simple expiration time will
be passed along, e.g. not "expires_variance".
If set to a number greater than 1 (e.g. 1.25), the time until expiration will be
multiplied by that number before being passed to the backend driver. This gives you a
customizable window of opportunity to retrieve expired items.
key_digester [STRING|HASHREF|OBJECT]
Digest algorithm to use on keys longer than "max_key_length" - e.g. "MD5", "SHA-1", or
"SHA-256".
Can be a Digest object, or a string or hashref which will passed to Digest->new(). You
will need to ensure Digest is installed to use these options.
Default is "MD5".
key_serializer [STRING|HASHREF|OBJECT]
An object to use for serializing keys that are references. See "serializer" above for
the different ways this can be passed in. The default is to use the JSON backend in
canonical mode (sorted hash keys).
label [STRING]
A label for the cache as a whole, independent of namespace - e.g. "web-file-cache".
Used when referring to the cache in logs, statistics, and error messages. By default,
set to "short_driver_name".
l1_cache [HASHREF]
Add an L1 cache as a subcache. See "SUBCACHES".
max_key_length [INT]
Keys over this size will be digested. The default is driver-specific;
CHI::Driver::File, for example, defaults this to 240 due to file system limits. For
most drivers there is no maximum.
mirror_cache [HASHREF]
Add an mirror cache as a subcache. See "SUBCACHES".
namespace [STRING]
Identifies a namespace that all cache entries for this object will be in. This allows
easy separation of multiple, distinct caches without worrying about key collision.
Suggestions for easy namespace selection:
• In a class, use the class name:
my $cache = CHI->new(namespace => __PACKAGE__, ...);
• In a script, use the script's absolute path name:
use Cwd qw(realpath);
my $cache = CHI->new(namespace => realpath($0), ...);
• In a web template, use the template name. For example, in Mason, $m->cache will
set the namespace to the current component path.
Defaults to 'Default' if not specified.
on_get_error [STRING|CODEREF]
on_set_error [STRING|CODEREF]
How to handle runtime errors occurring during cache gets and cache sets, which may or
may not be considered fatal in your application. Options are:
• log (the default) - log an error, or ignore if no logger is set - see "LOGGING"
• ignore - do nothing
• warn - call warn() with an appropriate message
• die - call die() with an appropriate message
• coderef - call this code reference with three arguments: an appropriate message,
the key, and the original raw error message
serializer [STRING|HASHREF|OBJECT]
An object to use for serializing data before storing it in the cache, and
deserializing data after retrieving it from the cache. Only references will be
serialized; plain scalars will be placed in the cache as-is.
If this is a string, a Data::Serializer object will be created, with the string passed
as the 'serializer' option and raw=1. Common options include 'Storable',
'Data::Dumper', and 'YAML'. If this is a hashref, Data::Serializer will be called with
the hash. You will need to ensure Data::Serializer is installed to use these options.
Otherwise, this must be a Data::Serializer object or another object that implements
serialize() and deserialize().
e.g.
# Serialize using raw Data::Dumper
my $cache = CHI->new(serializer => 'Data::Dumper');
# Serialize using Data::Dumper, compressed and (per Data::Serializer defaults) hex-encoded
my $cache = CHI->new(serializer => { serializer => 'Data::Dumper', compress => 1 });
# Serialize using custom object
my $cache = CHI->new(serializer => My::Custom::Serializer->new())
The default is to use raw Storable.
traits [LISTREF]
List of one or more roles to apply to the "CHI::Driver" class that is constructed. The
roles will automatically be prefixed with "CHI::Driver::Role::" unless preceded with a
'+'. e.g.
traits => ['StoresAccessedAt', '+My::CHI::Driver::Role']
INSTANCE METHODS
The following methods can be called on any cache handle returned from CHI->new(). They are
implemented in the CHI::Driver package.
Getting and setting
get( $key, [option => value, ...] )
Returns the data associated with $key. If $key does not exist or has expired, returns
undef. Expired items are not automatically removed and may be examined with
"get_object" or "get_expires_at".
$key may be followed by one or more name/value parameters:
expire_if [CODEREF]
If $key exists and has not expired, call code reference with the CHI::CacheObject
and CHI::Driver as the parameters. If code returns a true value, "get" returns
undef as if the item were expired. For example, to treat the cache as expired if
$file has changed since the value was computed:
$cache->get('foo', expire_if => sub { $_[0]->created_at < (stat($file))[9] });
busy_lock [DURATION]
If the value has expired, the get will still return undef, but the expiration time
of the cache entry will be set to the current time plus the specified duration.
This is used to prevent multiple processes from recomputing the same expensive
value simultaneously. The problem with this technique is that it doubles the
number of writes performed - see "expires_variance" for another technique.
obj_ref [SCALARREF]
If the item exists in cache (even if expired), place the CHI::CacheObject object
in the provided SCALARREF.
set( $key, $data, [$expires_in | "now" | "never" | options] )
Associates $data with $key in the cache, overwriting any existing entry. Returns
$data.
The third argument to "set" is optional, and may be either a scalar or a hash
reference. If it is a scalar, it may be the string "now", the string "never", or else
a duration treated as an expires_in value described below. If it is a hash reference,
it may contain one or more of the following options. Most of these options can be
provided with defaults in the cache constructor.
expires_in [DURATION]
Amount of time from now until this data expires. DURATION may be an integer number
of seconds or a duration expression.
expires_at [INT]
The epoch time at which the data expires.
expires_variance [FLOAT]
Controls the variable expiration feature, which allows items to expire a little
earlier than the stated expiration time to help prevent cache miss stampedes.
Value is between 0.0 and 1.0, with 0.0 meaning that items expire exactly when
specified (feature is disabled), and 1.0 meaning that items might expire anytime
from now until the stated expiration time. The default is 0.0. A setting of 0.10
to 0.25 would introduce a small amount of variation without interfering too much
with intended expiration times.
The probability of expiration increases as a function of how far along we are in
the potential expiration window, with the probability being near 0 at the
beginning of the window and approaching 1 at the end.
For example, in all of the following cases, an item might be considered expired
any time between 15 and 20 minutes, with about a 20% chance at 16 minutes, a 40%
chance at 17 minutes, and a 100% chance at 20 minutes.
my $cache = CHI->new ( ..., expires_variance => 0.25, ... );
$cache->set($key, $value, '20 min');
$cache->set($key, $value, { expires_at => time() + 20*60 });
my $cache = CHI->new ( ... );
$cache->set($key, $value, { expires_in => '20 min', expires_variance => 0.25 });
CHI will make a new probabilistic choice every time it needs to know whether an
item has expired (i.e. it does not save the results of its determination), so you
can get situations like this:
my $value = $cache->get($key); # returns undef (indicating expired)
my $value = $cache->get($key); # returns valid value this time!
if ($cache->is_valid($key)) # returns undef (indicating expired)
if ($cache->is_valid($key)) # returns true this time!
Typical applications won't be affected by this, since the object is recomputed as
soon as it is determined to be expired. But it's something to be aware of.
compute( $key, $options, $code )
Combines the "get" and "set" operations in a single call. Attempts to get $key; if
successful, returns the value. Otherwise, calls $code and uses the return value as the
new value for $key, which is then returned. Caller context (scalar or list) is
respected.
$options can be undef, a scalar, or a hash reference. If it is undef, it has no
effect. If it is a scalar, it is treated as the "expires_in" duration and passed as
the third argument to "set". If it is a hash reference, it may contain name/value
pairs for both "get" and "set". e.g.
# No expiration
my $value = $cache->compute($key, undef, sub {
# compute and return value for $key here
});
# Expire in 5 minutes
my $value = $cache->compute($key, '5min', sub {
# compute and return value for $key here
});
# Expire in 5 minutes or when a particular condition occurs
my $value = $cache->compute($key,
{ expires_in => '5min', expire_if => sub { ... } },
sub {
# compute and return value for $key here
});
# List context
my @value = $cache->compute($key, '5min', sub {
...
return @some_list;
});
This method will eventually support the ability to recompute a value in the background
just before it actually expires, so that users are not impacted by recompute time.
Note: Prior to version 0.40, the last two arguments were in reverse order; both will
be accepted for backward compatibility. We think the coderef looks better at the end.
Removing and expiring
remove( $key )
Remove the data associated with the $key from the cache.
expire( $key )
If $key exists, expire it by setting its expiration time into the past. Does not
necessarily remove the data. Since this involves essentially setting the value again,
"remove" may be more efficient for some drivers.
Inspecting keys
is_valid( $key )
Returns a boolean indicating whether $key exists in the cache and has not expired.
Note: Expiration may be determined probabilistically if "expires_variance" was used.
exists_and_is_expired( $key )
Returns a boolean indicating whether $key exists in the cache and has expired. Note:
Expiration may be determined probabilistically if "expires_variance" was used.
get_expires_at( $key )
Returns the epoch time at which $key definitively expires. Returns undef if the key
does not exist or it has no expiration time.
get_object( $key )
Returns a CHI::CacheObject object containing data about the entry associated with
$key, or undef if no such key exists. The object will be returned even if the entry
has expired, as long as it has not been removed.
Atomic operations (ALPHA)
These methods combine both reading and writing of a cache entry in a single operation. The
names and behaviors were adapted from memcached <http://memcached.org/>.
Some drivers (e.g. CHI::Driver::Memcached::libmemcached, CHI::Driver::DBI) may implement
these as truly atomic operations, and will be documented thusly. The default
implementations are not atomic: the get and set occur discretely and another process could
potentially modify the cache in between them.
These operations are labeled ALPHA because we haven't yet figured out how they integrate
with other CHI features, in particular "SUBCACHES". APIs and behavior may change.
add( $key, $data, [$expires_in | "now" | "never" | options] )
Do a set, but only if $key is not valid in the cache.
replace( $key, $data, [$expires_in | "now" | "never" | options] )
Do a set, but only if $key is valid in the cache.
append( $key, $new_data)
Append $new_data to whatever value is currently associated with $key. Has no effect if
$key does not exist in the cache.
Returns true if $key was in the cache, false otherwise.
This is intended for simple string values only. For efficiency's sake, CHI won't
attempt to check for, or handle, the case where data is serialized or compressed; the
new data will simply be appended, and an error will most probably occur when you try
to retrieve the value.
Does not modify expiration or other metadata. If $key exists but is expired, it will
remain expired.
If you use a driver with the non-atomic (default) implementation, some appends may be
lost due to race conditions.
Namespace operations
clear( )
Remove all entries from the namespace.
get_keys( )
Returns a list of keys in the namespace. This may or may not include expired keys,
depending on the driver.
The keys may not look the same as they did when passed into "set"; they may have been
serialized, utf8 encoded, and/or digested (see "KEY AND VALUE TRANSFORMATIONS").
However, they may still be passed back into "get", "set", etc. to access the same
underlying objects. i.e. the following code is guaranteed to produce all key/value
pairs from the cache:
map { ($_, $c->get($_)) } $c->get_keys()
purge( )
Remove all entries that have expired from the namespace associated with this cache
instance. Warning: May be very inefficient, depending on the number of keys and the
driver.
get_namespaces( )
Returns a list of namespaces associated with the cache. This may or may not include
empty namespaces, depending on the driver.
Multiple key/value operations
The methods in this section process multiple keys and/or values at once. By default these
are implemented with the obvious map operations, but some cache drivers (e.g.
Cache::Memcached) can override them with more efficient implementations.
get_multi_arrayref( $keys )
Get the keys in list reference $keys, and return a list reference of the same length
with corresponding values or undefs.
get_multi_hashref( $keys )
Like "get_multi_arrayref", but returns a hash reference with each key in $keys mapping
to its corresponding value or undef. Will only work with scalar keys.
set_multi( $key_values, $set_options )
Set the multiple keys and values provided in hash reference $key_values. $set_options
is a scalar or hash reference, used as the third argument to set. Will only work with
scalar keys.
remove_multi( $keys )
Removes the keys in list reference $keys.
dump_as_hash( )
Returns a hash reference containing all the non-expired keys and values in the cache.
Property accessors
chi_root_class( )
Returns the name of the root class under which this object was created, e.g. "CHI" or
"My::CHI". See "SUBCLASSING AND CONFIGURING CHI".
driver_class( )
Returns the full name of the driver class. e.g.
CHI->new(driver=>'File')->driver_class
=> CHI::Driver::File
CHI->new(driver=>'+CHI::Driver::File')->driver_class
=> CHI::Driver::File
CHI->new(driver=>'+My::Driver::File')->driver_class
=> My::Driver::File
You should use this rather than "ref()". Due to some subclassing tricks CHI employs,
the actual class of the object is neither guaranteed nor likely to be the driver
class.
short_driver_name( )
Returns the name of the driver class, minus the CHI::Driver:: prefix, if any. e.g.
CHI->new(driver=>'File')->short_driver_name
=> File
CHI->new(driver_class=>'CHI::Driver::File')->short_driver_name
=> File
CHI->new(driver_class=>'My::Driver::File')->short_driver_name
=> My::Driver::File
Standard read-write accessors
expires_in
expires_at
expires_variance
label
on_get_error
on_set_error
Standard read-only accessors
namespace
serializer
Deprecated methods
The following methods are deprecated and will be removed in a later version:
is_empty
DURATION EXPRESSIONS
Duration expressions, which appear in the "set" command and various other parts of the
API, are parsed by Time::Duration::Parse. A duration is either a plain number, which is
treated like a number of seconds, or a number and a string representing time units where
the string is one of:
s second seconds sec secs
m minute minutes min mins
h hr hour hours
d day days
w week weeks
M month months
y year years
e.g. the following are all valid duration expressions:
25
3s
5 seconds
1 minute and ten seconds
1 hour
KEY AND VALUE TRANSFORMATIONS
CHI strives to accept arbitrary keys and values for caching regardless of the limitations
of the underlying driver.
Key transformations
• Keys that are references are serialized - see "key_serializer".
• Keys with wide (>255) characters are utf8 encoded.
• Keys exceeding the maximum length for the underlying driver are digested - see
"max_key_length" and "key_digester".
• For some drivers (e.g. CHI::Driver::File), keys containing special characters or
whitespace are escaped with URL-like escaping.
Note: All transformations above with the exception of escaping are one-way, meaning that
CHI does not attempt to undo them when returned from "get_keys"; and idempotent, meaning
that applying them a second time has no effect. So when you call "get_keys", the key you
get may not be exactly what you passed in, but you'll be able to pass that key in to get
the corresponding object.
Value transformations
• Values which are references are automatically serialized before storing, and
deserialized after retrieving - see "serializer".
• Values with their utf8 flag on are utf8 encoded before storing, and utf8 decoded after
retrieving.
SUBCACHES
It is possible to a cache to have one or more subcaches. There are currently two types of
subcaches: L1 and mirror.
L1 cache
An L1 (or "level one") cache sits in front of the primary cache, usually to provide faster
access for commonly accessed cache entries. For example, this places an in-process Memory
cache in front of a Memcached cache:
my $cache = CHI->new(
driver => 'Memcached',
servers => [ "10.0.0.15:11211", "10.0.0.15:11212" ],
l1_cache => { driver => 'Memory', global => 1, max_size => 1024*1024 }
);
On a "get", the L1 cache is checked first - if a valid value exists, it is returned.
Otherwise, the primary cache is checked - if a valid value exists, it is returned, and the
value is placed in the L1 cache with the same expiration time. In this way, items fetched
most frequently from the primary cache will tend to be in the L1 cache.
"set" operations are distributed to both the primary and L1 cache.
You can access the L1 cache with the "l1_cache" method. For example, this clears the L1
cache but leaves the primary cache intact:
$cache->l1_cache->clear();
Mirror cache
A mirror cache is a write-only cache that, over time, mirrors the content of the primary
cache. "set" operations are distributed to both the primary and mirror cache, but "get"
operations go only to the primary cache.
Mirror caches are useful when you want to migrate from one cache to another. You can
populate a mirror cache and switch over to it once it is sufficiently populated. For
example, here we migrate from an old to a new cache directory:
my $cache = CHI->new(
driver => 'File',
root_dir => '/old/cache/root',
mirror_cache => { driver => 'File', root_dir => '/new/cache/root' },
);
We leave this running for a few hours (or as needed), then replace it with
my $cache = CHI->new(
driver => 'File',
root_dir => '/new/cache/root'
);
You can access the mirror cache with the "mirror_cache" method. For example, to see how
many keys have made it over to the mirror cache:
my @keys = $cache->mirror_cache->get_keys();
Creating subcaches
As illustrated above, you create subcaches by passing the "l1_cache" and/or "mirror_cache"
option to the CHI constructor. These options, in turn, should contain a hash of options to
create the subcache with.
The cache containing the subcache is called the parent cache.
The following options are automatically inherited by the subcache from the parent cache,
and may not be overridden:
expires_at
expires_in
expires_variance
serializer
(Reason: for efficiency, we want to create a single cache object and store it in both
caches. The cache object contains expiration information and is dependent on the
serializer. At some point we could conceivably add code that will use a single object or
separate objects as necessary, and thus allow the above to be overridden.)
The following options are automatically inherited by the subcache from the parent cache,
but may be overridden:
namespace
on_get_error
on_set_error
All other options are initialized in the subcache as normal, irrespective of their values
in the parent.
It is not currently possible to pass an existing cache in as a subcache.
Common subcache behaviors
These behaviors hold regardless of the type of subcache.
The following methods are distributed to both the primary cache and subcache:
clear
expire
purge
remove
The following methods return information solely from the primary cache. However, you are
free to call them explicitly on the subcache. (Trying to merge in subcache information
automatically would require too much guessing about the caller's intent.)
get_keys
get_namespaces
get_object
get_expires_at
exists_and_is_expired
is_valid
dump_as_hash
Multiple subcaches
It is valid for a cache to have one of each kind of subcache, e.g. an L1 cache and a
mirror cache.
A cache cannot have more than one of each kind of subcache, but a subcache can have its
own subcaches, and so on. e.g.
my $cache = CHI->new(
driver => 'Memcached',
servers => [ "10.0.0.15:11211", "10.0.0.15:11212" ],
l1_cache => {
driver => 'File',
root_dir => '/path/to/root',
l1_cache => { driver => 'RawMemory', global => 1 }
}
);
Methods for parent caches
has_subcaches( )
Returns a boolean indicating whether this cache has subcaches.
l1_cache( )
Returns the L1 cache for this cache, if any. Can only be called if has_subcaches is
true.
mirror_cache( )
Returns the mirror cache for this cache, if any. Can only be called if has_subcaches
is true.
subcaches( )
Returns the subcaches for this cache, in arbitrary order. Can only be called if
has_subcaches is true.
Methods for subcaches
is_subcache( )
Returns a boolean indicating whether this is a subcache.
subcache_type( )
Returns the type of subcache as a string, e.g. 'l1_cache' or 'mirror_cache'. Can only
be called if is_subcache is true.
parent_cache( )
Returns the parent cache (weakened to prevent circular reference). Can only be called
if is_subcache is true.
Developing new kinds of subcaches
At this time, subcache behavior is hardcoded into CHI::Driver, so there is no easy way to
modify the behavior of existing subcache types or create new ones. We'd like to make this
more flexible eventually.
SIZE AWARENESS
If "is_size_aware" or "max_size" are passed to the constructor, the cache will be size
aware - that is, it will keep track of its own size (in bytes) as items are added and
removed. You can get a cache's size with "get_size".
Size aware caches generally keep track of their size in a separate meta-key, and have to
do an extra store whenever the size changes (e.g. on each set and remove).
Maximum size and discard policies
If a cache's size rises above its "max_size", items are discarded until the cache size is
sufficiently below the max size. (See "max_size_reduction_factor" for how to fine-tune
this.)
The order in which items are discarded is controlled with "discard_policy". The default
discard policy is 'arbitrary', which discards items in an arbitrary order. The available
policies and default policy can differ with each driver, e.g. the CHI::Driver::Memory
driver provides and defaults to an 'LRU' policy.
Appropriate drivers
Size awareness was chiefly designed for, and works well with, the CHI::Driver::Memory
driver: one often needs to enforce a maximum size on a memory cache, and the overhead of
tracking size in memory is negligible. However, the capability may be useful with other
drivers.
Some drivers - for example, CHI::Driver::FastMmap and CHI::Driver::Memcached - inherently
keep track of their size and enforce a maximum size, and it makes no sense to turn on
CHI's size awareness for these.
Also, for drivers that cannot atomically read and update a value - for example,
CHI::Driver::File - there is a race condition in the updating of size that can cause the
size to grow inaccurate over time.
SUBCLASSING AND CONFIGURING CHI
You can subclass CHI for your own application and configure it in a variety of ways, e.g.
predefining storage types and defaults for new cache objects. Your configuration will be
independent of the main CHI class and other CHI subclasses.
Start with a trivial subclass:
package My::CHI;
use base qw(CHI);
1;
Then, just use your subclass in place of CHI:
my $cache = My::CHI->new( ... );
print $cache->chi_root_class;
==> 'My::CHI'
This obviously doesn't change any behavior by itself. Here's an example with actual
config:
package My::CHI;
use base qw(CHI);
__PACKAGE__->config({
storage => {
local_file => { driver => 'File', root_dir => '/my/root' },
memcached => {
driver => 'Memcached::libmemcached',
servers => [ '10.0.0.15:11211', '10.0.0.15:11212' ]
},
},
namespace => {
'Foo' => { storage => 'local_file' },
'Bar' => { storage => 'local_file', depth => 3 },
'Baz' => { storage => 'memcached' },
}
defaults => { storage => 'local_file' },
memoize_cache_objects => 1,
});
1;
Each of these config keys is explained in the next section.
Configuration keys
storage
A map of names to parameter hashrefs. This provides a way to encapsulate common sets
of parameters that might be used in many caches. e.g. if you define
storage => {
local_file => { driver => 'File', root_dir => '/my/root' },
...
}
then
my $cache = My::CHI->new
(namespace => 'Foo', storage => 'local_file');
is equivalent to
my $cache = My::CHI->new
(namespace => 'Foo', driver => 'File', root_dir => '/my/root');
namespace
A map of namespace names to parameter hashrefs. When you create a cache object with
the specified namespace, the hashref of parameters will be applied as defaults. e.g.
if you define
namespace => {
'Foo' => { driver => 'File', root_dir => '/my/root' },
'Bar' => { storage => 'database' },
...
}
then
my $cache1 = My::CHI->new
(namespace => 'Foo');
my $cache2 = My::CHI->new
(namespace => 'Bar');
is equivalent to
my $cache1 = My::CHI->new
(namespace => 'Foo', driver => 'File', root_dir => '/my/root');
my $cache2 = My::CHI->new
(namespace => 'Bar', storage => 'database');
defaults
A hash of parameters that will be used as core defaults for all cache objects created
under this root class. e.g.
defaults => {
on_get_error => 'die',
expires_variance => 0.2,
}
These can be overridden by namespace defaults, storage settings, or "new" parameters.
memoize_cache_objects
True or false, indicates whether "My::CHI->new" should memoize and return the same
cache object if given the same parameters. This can speed things up if you create
cache objects frequently. Will currently only work for 0- or 1- key parameter hashes.
e.g.
My::CHI->config({
memoize_cache_objects => 1,
});
then
# $cache1 and $cache2 will be the same object, regardless of what
# namespace and storage defaults are associated with 'Foo'
#
my $cache1 = My::CHI->new(namespace => 'Foo');
my $cache2 = My::CHI->new(namespace => 'Foo');
# $cache3 and $cache4 will be different objects
#
my $cache3 = My::CHI->new
(namespace => 'Bar', driver => 'File', root_dir => '/my/root');
my $cache4 = My::CHI->new
(namespace => 'Bar', driver => 'File', root_dir => '/my/root');
To clear the memoized cache objects, call
My::CHI->clear_memoized_cache_objects;
How defaults are combined
Defaults are applied in the following order, from highest to lowest precedence:
• Parameters passed in "new"
• Namespace defaults, if any
• Storage settings, if any
• Core defaults defined under 'defaults'
Inheritance of config
A subclass will automatically inherit the configuration of its parent if it does not call
"config" itself (ala Class::Data::Inheritable).
Reading config from a file
use YAML::XS qw(LoadFile);
__PACKAGE__->config(LoadFile("/path/to/cache.yml"));
AVAILABILITY OF DRIVERS
The following drivers are currently available as part of this distribution:
• CHI::Driver::Memory - In-process memory based cache
• CHI::Driver::RawMemory - In-process memory based cache that stores references directly
instead of serializing/deep-copying
• CHI::Driver::File - File-based cache using one file per entry in a multi-level
directory structure
• CHI::Driver::FastMmap - Shared memory interprocess cache via mmap'ed files
• CHI::Driver::Null - Dummy cache in which nothing is stored
• CHI::Driver::CacheCache - CHI wrapper for Cache::Cache
The following drivers are currently available as separate CPAN distributions:
• CHI::Driver::Memcached - Distributed memory-based cache (works with Cache::Memcached,
Cache::Memcached::Fast, and Cache::Memcached::libmemcached)
• CHI::Driver::DBI - Cache in any DBI-supported database
• CHI::Driver::BerkeleyDB - Cache in BerkeleyDB files
• CHI::Driver::Redis - Cache in Redis <http://redis.io/>
• CHI::Driver::SharedMem - Cache in shared memory
This list is likely incomplete. A complete set of drivers can be found on CPAN by
searching for "CHI::Driver".
PERFORMANCE COMPARISON OF DRIVERS
See CHI::Benchmarks for a comparison of read/write times of both CHI and non-CHI cache
implementations.
"etc/bench/bench.pl" in the "CHI" distribution contains a script to run these types of
benchmarks on your own system.
DEVELOPING NEW DRIVERS
See CHI::Driver::Development for information on developing new drivers.
LOGGING
"CHI" uses Log::Any for logging events. For example, a debug log message is sent with
category "CHI::Driver" for every cache get and set.
See Log::Any documentation for how to control where logs get sent, if anywhere.
STATS
CHI can record statistics, such as number of hits, misses and sets, on a per-namespace
basis and log the results to your Log::Any logger. You can then use utilities included
with this distribution to read stats back from the logs and report a summary. See
CHI::Stats for details.
RELATION TO OTHER MODULES
Cache::Cache
CHI is intended as an evolution of DeWitt Clinton's Cache::Cache package. It starts with
the same basic API (which has proven durable over time) but addresses some implementation
shortcomings that cannot be fixed in Cache::Cache due to backward compatibility concerns.
In particular:
Performance
Some of Cache::Cache's subclasses (e.g. Cache::FileCache) have been justifiably
criticized as inefficient. CHI has been designed from the ground up with performance
in mind, both in terms of general overhead and in the built-in driver classes. Method
calls are kept to a minimum, data is only serialized when necessary, and metadata such
as expiration time is stored in packed binary format alongside the data.
Ease of subclassing
New Cache::Cache subclasses can be tedious to create, due to a lack of code
refactoring, the use of non-OO package subroutines, and the separation of "cache" and
"backend" classes. With CHI, the goal is to make the creation of new drivers as easy
as possible, roughly the same as writing a TIE interface to your data store. Concerns
like serialization and expiration options are handled by the driver base class so that
individual drivers don't have to worry about them.
Increased compatibility with cache implementations
Probably because of the reasons above, Cache::Cache subclasses were never created for
some of the most popular caches available on CPAN, e.g. Cache::FastMmap and
Cache::Memcached. CHI's goal is to be able to support these and other caches with a
minimum performance overhead and minimum of glue code required.
Cache
The Cache distribution is another redesign and implementation of Cache, created by Chris
Leishman in 2003. Like CHI, it improves performance and reduces the barrier to
implementing new cache drivers. It breaks with the Cache::Cache interface in a few ways
that I considered non-negotiable - for example, get/set do not serialize data, and
namespaces are an optional feature that drivers may decide not to implement.
Cache::Memcached, Cache::FastMmap, etc.
CPAN sports a variety of full-featured standalone cache modules representing particular
backends. CHI does not reinvent these but simply wraps them with an appropriate driver.
For example, CHI::Driver::Memcached and CHI::Driver::FastMmap are thin layers around
Cache::Memcached and Cache::FastMmap.
Of course, because these modules already work on their own, there will be some overlap.
Cache::FastMmap, for example, already has code to serialize data and handle expiration
times. Here's how CHI resolves these overlaps.
Serialization
CHI handles its own serialization, passing a flat binary string to the underlying
cache backend. The notable exception is CHI::Driver::RawMemory which does no
serialization.
Expiration
CHI packs expiration times (as well as other metadata) inside the binary string passed
to the underlying cache backend. The backend is unaware of these values; from its
point of view the item has no expiration time. Among other things, this means that you
can use CHI to examine expired items (e.g. with $cache->get_object) even if this is
not supported natively by the backend.
At some point CHI will provide the option of explicitly notifying the backend of the
expiration time as well. This might allow the backend to do better storage management,
etc., but would prevent CHI from examining expired items.
Naturally, using CHI's FastMmap or Memcached driver will never be as time or storage
efficient as simply using Cache::FastMmap or Cache::Memcached. In terms of performance,
we've attempted to make the overhead as small as possible, on the order of 5% per get or
set (benchmarks coming soon). In terms of storage size, CHI adds about 16 bytes of
metadata overhead to each item. How much this matters obviously depends on the typical
size of items in your cache.
SUPPORT AND DOCUMENTATION
Questions and feedback are welcome, and should be directed to the perl-cache mailing list:
http://groups.google.com/group/perl-cache-discuss
Bugs and feature requests will be tracked at RT:
http://rt.cpan.org/NoAuth/Bugs.html?Dist=CHI
bug-chi@rt.cpan.org
The latest source code can be browsed and fetched at:
http://github.com/jonswar/perl-chi/tree/master
git clone git://github.com/jonswar/perl-chi.git
ACKNOWLEDGMENTS
Thanks to Dewitt Clinton for the original Cache::Cache, to Rob Mueller for the Perl cache
benchmarks, and to Perrin Harkins for the discussions that got this going.
CHI was originally designed and developed for the Digital Media group of the Hearst
Corporation, a diversified media company based in New York City. Many thanks to Hearst
management for agreeing to this open source release.
SEE ALSO
Cache::Cache
AUTHOR
Jonathan Swartz <swartz@pobox.com>
COPYRIGHT AND LICENSE
This software is copyright (c) 2012 by Jonathan Swartz.
This is free software; you can redistribute it and/or modify it under the same terms as
the Perl 5 programming language system itself.